Effect of the sequences upstream from the ribosome-binding site on the yield of protein from the cloned gene for phage MS2 coat protein

In vitro characterisation of the MS2 RNA polymerase complex reveals host factors that modulate emesviral replicase activity

The RNA phage MS2 is one of the most important model organisms in molecular biology and virology. Despite its comprehensive characterisation, the composition of the RNA replication machinery remained obscure. Here, we characterised host proteins required to reconstitute the functional replicase in vitro. By combining a purified replicase sub-complex with elements of an in vitro translation system, we confirmed that the three host factors, EF-Ts, EF-Tu, and ribosomal protein S1, are part of the active replicase holocomplex. Furthermore, we found that the translation initiation factors IF1 and IF3 modulate replicase activity. While IF3 directly competes with the replicase for template binding, IF1 appears to act as an RNA chaperone that facilitates polymerase readthrough. Finally, we demonstrate in vitro formation of RNAs containing minimal motifs required for amplification. Our work sheds light on the MS2 replication machinery and provides a new promising platform for cell-free evolution.

ssRNA Phages: Life Cycle, Structure and Applications

ssRNA phages belonging to the family Leviviridae are among the tiniest viruses, infecting various Gram-negative bacteria by adsorption to their pilus structures. Due to their simplicity, they have been intensively studied as models for understanding various problems in molecular biology and virology. Several of the studied ssRNA characteristics, such as coat protein–RNA interactions and the ability to readily form virus-like particles in recombinant expression systems, have fueled many practical applications such as RNA labeling and tracking systems and vaccine development. In this chapter, we review the life cycle, structure and applications of these small yet fascinating viruses.

Unstructured 5'-tails act through ribosome standby to override inhibitory structure at ribosome binding sites

Initiation is the rate-limiting step in translation. It is well-known that stable structure at a ribosome binding site (RBS) impedes initiation. The ribosome standby model of de Smit and van Duin, based on studies of the MS2 phage coat cistron, proposed how high translation rates can be reconciled with stable, inhibitory structures at an RBS. Here, we revisited the coat protein system and assessed the translation efficiency from its sequestered RBS by introducing standby mutations. Further experiments with gfp reporter constructs assessed the effects of 5′-tails—as standby sites—with respect to length and sequence contributions. In particular, combining in vivo and in vitro assays, we can show that tails of CA-dinucleotide repeats—and to a lesser extent, AU-repeats—dramatically increase translation rates. Tails of increasing length reach maximal rate-enhancing effects at 16–18 nucleotides. These standby tails are single-stranded and do not exert their effect by structure changes in the neighboring RBS stem–loop. In vitro translation and toeprinting assays furthermore demonstrate that standby effects are exerted at the level of translation initiation. Finally, as expected, destabilizing mutations within the coat RBS indicate an interplay with the effects of standby tails.

Production and characterization of novel ssRNA bacteriophage virus-like particles from metagenomic sequencing data

Background

Protein shells assembled from viral coat proteins are an attractive platform for development of new vaccines and other tools such as targeted bioimaging and drug delivery agents. Virus-like particles (VLPs) derived from the single-stranded RNA (ssRNA) bacteriophage coat proteins (CPs) have been important and successful contenders in the area due to their simplicity and robustness. However, only a few different VLP types are available that put certain limitations on continued developments and expanded adaptation of ssRNA phage VLP technology. Metagenomic studies have been a rich source for discovering novel viral sequences, and in recent years have unraveled numerous ssRNA phage genomes significantly different from those known before. Here, we describe the use of ssRNA CP sequences found in metagenomic data to experimentally produce and characterize novel VLPs.

Results

Approximately 150 ssRNA phage CP sequences were sourced from metagenomic sequence data and grouped into 14 different clusters based on CP sequence similarity analysis. 110 CP-encoding sequences were obtained by gene synthesis and expressed in bacteria which in 80 cases resulted in VLP assembly. Production and purification of the VLPs was straightforward and compatible with established protocols, with the only exception that a considerable proportion of the CPs had to be produced at a lower temperature to ensure VLP assembly. The VLP morphology was similar to that of the previously studied phages, although a few deviations such as elongated or smaller particles were noted in certain cases. In addition, stabilizing inter-subunit disulfide bonds were detected in six VLPs and several possible candidate RNA structures in the phage genomes were identified that might bind to the coat protein and ensure specific RNA packaging.

Conclusions

Compared to the few types of ssRNA phage VLPs that were used before, several dozens of new particles representing ten distinct similarity groups are now available with a notable potential for biotechnological applications. It is believed that the novel VLPs described in this paper will provide the groundwork for future development of new vaccines and other applications based on ssRNA bacteriophage VLPs.

Electronic supplementary material

The online version of this article (10.1186/s12951-019-0497-8) contains supplementary material, which is available to authorized users.

Protein-RNA Interactions in the Single-Stranded RNA Bacteriophages

Bacteriophages of the Leviviridae family are small viruses with short single-stranded RNA (ssRNA) genomes. Protein-RNA interactions play a key role throughout the phage life cycle, and all of the conserved phage proteins - the maturation protein, the coat protein and the replicase - are able to recognize specific structures in the RNA genome. The phage-coded replicase subunit associates with several host proteins to form a catalytically active complex. Recognition of the genomic RNA by the replicase complex is achieved in a remarkably complex manner that exploits the RNA-binding properties of host proteins and the particular three-dimensional structure of the phage genome. The coat protein recognizes a hairpin structure at the beginning of the replicase gene. The binding interaction serves to regulate the expression of the replicase gene and can be remarkably different in various ssRNA phages. The maturation protein is a minor structural component of the virion that binds to the genome, mediates attachment to the host and guides the genome into the cell. The maturation protein has two distinct RNA-binding surfaces that are in contact with different regions of the genome. The maturation and coat proteins also work together to ensure the encapsidation of the phage genome in new virus particles. In this chapter, the different ssRNA phage protein-RNA interactions, as well as some of their practical applications, are discussed in detail.

Assembly of mixed rod-like and spherical particles from group I and II RNA bacteriophage coat proteins

The capsids of single-stranded RNA bacteriophages show remarkable structural similarity. In an attempt to test whether the coat protein (CP) from one bacteriophage could substitute for the CP of another and form mixed particles, we reassembled capsids in vitro from a mixture of different RNA phage CP dimers together with E. coli ribosomal RNA. Surprisingly, mixing CPs from phages belonging to groups I and II led to appearance of rod-like particles along with icosahedral spherical capsids, both containing a mixture of the two CPs. Rods and mixed spherical capsids containing host RNA were also obtained in vivo in bacteria expressing simultaneously fr and GA CPs. In a co-infection of the two phages, however, only authentic fr and GA virions were formed. Coat protein mutants in the FG loop were unable to assemble into rods, suggesting that these loops are involved in the formation of the aberrant particles.

Mutilation of RNA phage Qbeta virus-like particles: from icosahedrons to rods

Icosahedral virus-like particles (VLPs) of RNA phage Qbeta are stabilized by four disulfide bonds of cysteine residues 74 and 80 within the loop between beta-strands F and G (FG loop) of the monomeric subunits, which determine the five-fold and quasi-six-fold symmetry contacts of the VLPs. In order to reduce the stability of Qbeta VLPs, we mutationally converted the amino acid stretch 76-ANGSCD-81 within the FG loop into the 76-VGGVEL-81 sequence. It led to production in Escherichia coli cells of aberrant rod-like Qbeta VLPs, along with normal icosahedral capsids. The length of the rod-like particles exceeded 4-30 times the diameter of icosahedral Qbeta VLPs.

Expression and immunogenicity of a liver stage malaria epitope presented as a foreign peptide on the surface of RNA-free MS2 bacteriophage capsids

We have designed a novel vaccine strategy which enables display of short peptides expressed from chimeras of the gene encoding the coat protein of the RNA bacteriophage MS2 and inserted foreign DNA. MS2 coat protein has a beta-hairpin loop at the N-terminus which forms the most radially distinct feature of the mature capsid. The coat protein gene was modified to enable insertion of DNA at the central part of the beta-hairpin loop. Upon expression of the recombinant gene in E. coli, the MS2 coat protein subunits self-assemble into capsids, each comprising 180 copies of the monomer. This system was used to produce chimeras containing a putatively protective epitope, T1, from the immunodominant liver stage antigen-1 (LSA-1) of the malaria parasite Plasmodium falciparum. The immunogenicity of the native MS2 capsid and the recombinant construct was investigated in BALB/c (H-2(d)) mice. The native protein appeared to elicit both humoral and cellular immune responses, observed as a predominance of type 2 cytokines but with a mixed profile of immunoglobulin isotypes. In contrast, the LSA-1 chimera stimulated a type 1-polarised response, with significant upregulation of interferon-gamma, a finding which corroborates naturally acquired resistance to liver stage malaria. These results validate RNA phage capsid display of immunogenic determinants as a basis for the development of novel peptide vaccines and indicate that further evaluation of MS2 coat protein as a vector for malaria epitopes is merited.

Direct genetic selection of two classes of R17/MS2 coat proteins with altered capsid assembly properties and expanded RNA-binding activities

RNA challenge phages are derivatives of bacteriophage P22 that enable direct genetic selection for a specific RNA-protein interaction. The bacteriophage P22 R17 encodes a wild-type R17 operator site and undergoes lysogenic development following infection of susceptible bacterial strains that express the R17/MS2 coat protein. A P22 R17 derivative with an OcRNA site (P22 R17 [A(-10)U]) develops lytically following infection of these strains. RNA challenge phages can be used to isolate second-site coat protein suppressors that recognize an OcRNA sequence by selecting for lysogens with a P22 R17 [Oc] phage derivative. The bacteriophage derivative P22 R17 [A(-10)U] was used in one such scheme to isolate two classes of genes that encode R17 coat proteins with altered capsid assembly properties and expanded RNA-binding characteristics. These mutations map outside the RNA-binding surface and include amino acid substitutions that interfere with interactions between coat protein dimers in the formation of the stable phage capsid. One class of mutants encodes substitutions at the highly conserved first and second positions of the mature coat protein. N-terminal sequence analysis of these mutants reveals that coat proteins with substitutions only at position 1 are defective in post-translational processing of the initiator methionine. All selected proteins possess expanded RNA-binding properties since they direct efficient lysogen formation for P22 R17 and P22 R17 [A(-10)U]; however, bacterial strains that express the protein mutants remain sensitive to lytic infection by other P22 R17 [Oc] bacteriophages. The described selection strategy provides a novel genetic approach to dissecting protein structure within RNA-binding proteins.

Vitamin B12 repression of the cob operon in Salmonella typhimurium: translational control of the cbiA gene

Expression of the cob operon is repressed by B12 via a post-transcriptional control mechanism which requires sequence elements within the leader region of the mRNA and the first gene of the operon, the cbiA gene. Here we show that B12 repression of cbiA gene expression occurs at the level of translation initiation through sequestration of the ribosomal binding site (rbs) in an RNA hairpin. Analysis of mutations that destabilize or restabilize the secondary structure demonstrates that folding of the hairpin is essential for repression. The existence of the hairpin was confirmed by a secondary structure analysis of RNA from the wild type and three mutants. Deletions that remove the upstream part of the leader confer a drastic reduction in translation efficiency. This low-level translation is caused by the hairpin, as indicated by the finding that suppressor mutations that destabilize the hairpin restore efficient translation. Thus, the native upstream RNA functions as a translation enhancer and acts to relieve the hairpin's inhibitory effect on translation initiation. The inhibitory effect of the hairpin was confirmed by a ribosomal toeprinting analysis. We propose that the translational control of the cbiA gene mediates repression of the entire cob operon.

Translational initiation on structured messengers. Another role for the Shine-Dalgarno interaction

Translational efficiency in Escherichia coli is in part determined by the Shine-Dalgarno (SD) interaction, i.e. the base-pairing of the 3' end of 16S ribosomal RNA to a stretch of complementary nucleotides in the messenger, located just upstream of the initiation codon. Although a large number of mutations in SD sequences have been produced and analysed, it has so far not been possible to find a clear-cut quantitative relationship between the extent of the complementarity to the rRNA and translational efficiency. This is presumably due to a lack of information about the secondary structures of the messengers used, before and after mutagenesis. Such information is crucial, because intrastrand base-pairing of a ribosome binding site can have a profound influence on its translational efficiency. By site-directed mutagenesis, we have varied the extent of the SD complementarity in the coat-protein gene of bacteriophage MS2. The ribosome binding site of this gene is known to adopt a simple hairpin structure. Substitutions in the SD region were combined with other mutations, which altered the stability of the structure in a predictable way. We find that mutations reducing the SD complementarity by one or two nucleotides diminish translational efficiency only if ribosome binding is impaired by the structure of the messenger. In the absence of an inhibitory structure, these mutations have no effect. In other words, a strong SD interaction can compensate for a structured initiation region. This can be understood by considering translational initiation on a structured ribosome binding site as a competition between intramolecular base-pairing of the messenger and binding to a 30 S ribosomal subunit. A good SD complementarity provides the ribosome with an increased affinity for its binding site, and thereby enhances its ability to compete against the secondary structure. This function of the SD interaction closely parallels the RNA-unfolding capacity of ribosomal protein S1. By comparing the expression data from mutant and wild-type SD sequences, we have estimated the relative contribution of the SD base-pairs to ribosome-mRNA affinity. Quantitatively, this contribution corresponds quite well with the theoretical base-pairing stabilities of the wild-type and mutant SD interactions.

An unstructured mRNA region and a 5' hairpin represent important elements of the E. coli translation initiation signal determined by using the bacteriophage T7 gene 1 translation start site

Gene 1 of bacteriophage T7 early region--the RNA polymerase gene--is very actively translated during the infectious cycle of this phage. A 29 base pair fragment of its ribosome binding site containing the initiation triplet, the Shine-Dalgarno sequence (S-D), 10 nucleotides (nt) upstream and 6 nt downstream of these central elements was cloned into a vector to control the expression of the mouse dihydrofolate reductase gene (dhfr). Although all essential parts of this translation initiation region (TIR) should be present, this fragment showed only very low activity. Computer analysis revealed a potentially inhibitory hairpin binding the S-D sequence into its stem base paired to vector-derived upstream sequences. Mutational alterations demonstrated that this hairpin was not responsible for the low activity. However, addition of 21 nt of the T7 gene 1 upstream sequence to the 29 base pair fragment were capable of increasing the translational efficiency by one order of magnitude. Computer analysis of this sequence, including nucleotide shuffling, revealed that it contains a highly unstructured region lacking mRNA secondary structures but with a hairpin at its 5' end, here formed solely by T7 sequences. There was not much difference in activity whether the mRNA included or lacked vector-derived sequences upstream of the hairpin. Such highly unstructured mRNA regions were found in all very efficiently expressed T7 genes without any obvious sequence homologies. The delta G values of these regions were higher, i.e. potential secondary structural elements were fewer, than in TIR of genes from E. coli. This is likely due to the fact that T7 as a lytic phage is relying for successful infection on much stronger signals which a cell cannot afford because of the indispensable balanced equilibria of its interdependent biochemical processes. When the 5' ends of efficient T7 gene mRNA are formed by the action of RNase III they generally start with an unstructured region. Efficiently expressed T7 genes within a polycistronic mRNA, however, always contain a hairpin preceding the structure free sequence. We suggest that the formation of this 5' hairpin is releasing enough energy to keep the unstructured regions free of secondary RNA structures for sufficient time to give ribosomes and factors a good chance for binding to the TIR. In addition, sequences further downstream of the start codon give rise to an additional increase in efficiency of the TIR by almost two orders of magnitude.

Translational initiation at the coat-protein gene of phage MS2: native upstream RNA relieves inhibition by local secondary structure

Maximal translation of the coat-protein gene from RNA bacteriophage MS2 requires a contiguous stretch of native MS2 RNA that extends hundreds of nucleotides upstream from the translational start site. Deletion of these upstream sequences from MS2 cDNA plasmids results in a 30-fold reduction of translational efficiency. By site-directed mutagenesis, we show that this low level of expression is caused by a hairpin structure centred around the initiation codon. When this hairpin is destabilized by the introduction of mismatches, expression from the truncated messenger increases 20-fold to almost the level of the full-length construct. Thus, the translational effect of hundreds of upstream nucleotides can be mimicked by a single substitution that destabilizes the structure. The same hairpin is also present in full-length MS2 RNA, but there it does not impair ribosome binding. Apparently, the upstream RNA somehow reduces the inhibitory effect of the structure on translational initiation. The upstream MS2 sequence does not stimulate translation when cloned in front of another gene, nor can unrelated RNA segments activate the coat-protein gene. Several possible mechanisms for the activation are discussed and a function in gene regulation of the phage is suggested.

Secondary structure of the central region of bacteriophage MS2 RNA. Conservation and biological significance

The RNA of the Escherichia coli RNA phages is highly structured with 75% of the nucleotides estimated to take part in base-pairing. We have used enzymatic and chemical sensitivity of nucleotides, phylogenetic sequence comparison and the phenotypes of constructed mutants to develop a secondary structure model for the central region (900 nucleotides) of the group I phage MS2. The RNA folds into a number of, mostly irregular, helices and is further condensed by several long-distance interactions. There is substantial conservation of helices between the related groups I and II, attesting to the relevance of discrete RNA folding. In general, the secondary structure is thought to be needed to prevent annealing of plus and minus strand and to confer protection against RNase. Superimposed, however, are features required to regulate translation and replication. The MS2 RNA section studied here contains three translational start sites, as well as the binding sites for the coat protein and the replicase enzyme. Considering the density of helices along the RNA, it is not unexpected to find that all these sites lie in helical regions. This fact, however, does not mean that these sites are recognized as secondary structure elements by their interaction partners. This holds true only for the coat protein binding site. The other four sites function in the unfolded state and the stability of the helix in which they are contained serves to negatively control their accessibility. Mutations that stabilize helices containing ribosomal binding sites reduce their efficiency and vice versa. Comparison of homologous helices in different phage RNAs indicates that base substitutions have occurred in such a way that the thermodynamic stability of the helix is maintained. The evolution of individual helices shows several distinct size-reduction patterns. We have observed codon deletions from loop areas and shortening of hairpins by base-pair deletions from either the bottom, the middle or the top of stem structures. Evidence for the coaxial stacking of some helical segments is discussed.

The role of bases upstream of the Shine-Dalgarno region and in the coding sequence in the control of gene expression in Escherichia coli: translation and stability of mRNAs in vivo

A range of translational initiation regions (TIR) was created by combining synthetic DNA fragments derived from the atpB-atpE intercistronic sequence of Escherichia coli with the cDNA sequence encoding mature human interleukin 2 (IL-2), the E. coli fnr gene, or an fnr::lacZ gene fusion. Both the overall rates of gene expression and the relative concentrations and stabilities of the corresponding mRNA species were estimated in strains bearing the constructs on plasmids. These measurements served as the basis for analyses of the relationship between the structure of the TIR and the true rates of translation that it promotes. The constructs involving the IL-2 cDNA were predicted to allow much less stable secondary structure within the TIR than those involving the N-terminal region of the fnr gene. Thus by combining one set of upstream sequences with two different types of N-terminal coding sequence, it was possible to distinguish between the respective influences of primary and secondary structure upon initiation. The data indicate that in the presence of a given Shine-Dalgarno (SD)/start codon combination, the decisive factor for translational initiation efficiency is the stability of base pairing involving, or in the vicinity of, this region. The sequences contributing to this secondary structure can be many bases upstream of the SD region and/or downstream of the start codon. There was no indication that the specific base sequence upstream of the SD region could, other than to the extent that it contributed to the local secondary structure, significantly influence the efficiency of translational initiation.

An additional ribosome-binding site on mRNA of highly expressed genes and a bifunctional site on the colicin fragment of 16S rRNA from Escherichia coli: important determinants of the efficiency of translation-initiation

For various genes of E. coli, three regions (-55 to -1; -35 to -1; -21 to -1) 5' to AUG codon on mRNA were searched for sites of interaction with colicin fragment of 16S rRNA. The detailed sequence comparison points out that apart from Shine-Dalgarno base pairing, an additional ribosome-binding site, a subsequence of 5'-UGAUCC-3' invariably exists in mRNA for highly expressed genes. Poorly expressed genes appear to be controlled by only Shine-Dalgarno base pairing. The analysis indicates that in the initiator region, the -55 to -1 region contains the signal which decides the efficiency of the translation-initiation. The site on 16S rRNA, 5'-GGAUCA-3' at position 1529, that can base pair to the above site, has a recognition site on 23S rRNA at position 2390. In the light of the conserved nature and accessibility of these sites, it is proposed that the site on 16S rRNA plays a bifunctional role--initially it binds to mRNA from highly expressed genes to form a stable 30S initiation complex, and upon association with 50S subunit it exchanges base pairing with 23S rRNA, thus leaving the site on mRNA free.

Coliphage lambda to terminator lowers the stability of messenger RNA in Escherichia coli hosts

The effects of the transcription terminators to and tfd on the overall high-level expression of a human interferon-beta gene (IFN-beta) in Escherichia coli hosts were compared. Deletion mapping shows that mRNA lability is caused by sequences at or near the lambda terminator to stem-loop structure. Extensive RNA secondary structure in this region indicates a potential RNase III cleavage/binding site. In RNase III- E. coli hosts, IFN-beta synthesis is indeed considerably enhanced. The bacteriophage tfd terminator does not confer this mRNA labilization phenomenon. In all cases, RNA level and stability correlate with the level of IFN-beta synthesized in the cell. In the system described, ongoing translation stabilizes mRNA only moderately.

Relationship between size of mRNA ribosomal binding site and initiation factor function

The rate and the extent of the binding of initiator fMet-tRNA(fMet) to 30S ribosomal subunits in the presence of IF1, IF2 and GTP is either inhibited or slightly stimulated by the presence of IF3 depending on whether the initiation triplet AUG or the polynucleotide poly(AUG) is used as template. To determine the length of the template required for the transition from the AUG- to the poly(AUG)-type of behavior in the presence of IF3, the ribosomal binding of fMet-tRNA was studied in response to AUG triplets extended on either the 5'- or the 3'-side by stretches of homo-oligonucleotides of different lengths. When the binding of fMet-tRNA was studied at equilibrium it was found that IF3 no longer inhibits the amount of ternary complex formed if AUG is extended either 10 nucleotides on the 5'- or 35-40 nucleotides on the 3'-side. When the initial rate of ternary complex formation is considered, shorter extensions (4 nucleotides on the 5'-side or 20-30 nucleotides on the 3'-side) are sufficient to elicit a substantial stimulation by IF3. These results are discussed in relation to the mechanism of action of the initiation factors in the selection of the initiation region of the mRNA by ribosomes.

The extracellular portion of HLA-DR alpha chain is composed of two compactly folded domains

A truncated form of the class II antigen DR alpha chain of the human major histocompatibility complex was produced in bacteria. A cDNA clone encoding the intact chain was modified so that the segment encoding the signal sequence was replaced by an ATG codon and the 3' region downstream to the part corresponding to the third exon was replaced by a stop codon. The new construct was put under the control of the Tac promoter in a bacterial expression vector. The distance between the Shine-Delgarno sequence and the initiation codon was randomized so that clones with optimal expression of the truncated DR alpha chain could be obtained after induced expression and immunoscreening. The truncated DR alpha chain was subjected to limited proteolysis with chymotrypsin, and the resulting cleavage products were analysed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Two fragments were visualized by western blotting. Electrophoresis in the absence and presence of reducing agents suggested that one of the proteolytic fragments contained a disulphide bridge. It is concluded that the extracellular portion of the DR alpha chain is composed of two compactly folded domains connected by an extended stretch of the polypeptide chain.

Mutational alterations of translational coupling in the L11 ribosomal protein operon of Escherichia coli

The L11 operon in Escherichia coli consists of the genes coding for ribosomal proteins L11 and L1. It is known that translation of L1 does not take place unless the preceding L11 cistron is translated, that is, the two cistrons are translationally coupled, and this is the basis of coregulation of the translation of the two cistrons by a single repressor, L1. Several mutational analyses were carried out to define the region responsible for coupling L1 translation with L11 translation. First, by introducing several amber mutations into the L11 gene by a site-directed mutagenesis technique, it was shown that translation by ribosomes down to a position 21 nucleotides upstream, but not to a position 45 nucleotides upstream, from the end of the L11 cistron allowed the initiation of L11 translation. Second, deletion analysis indicated that a region located 23 to 20 nucleotides from the end of the L11 gene was involved in preventing independent initiation from L1 translation. Third, five different mutations obtained by screening for activation of the masked L1 initiation site were found to be clustered in a small region immediately upstream from the Shine-Dalgarno sequence of L1, and all of them were G-to-A transitions. These results, together with some additional experiments with oligonucleotide-directed mutagenesis, defined the region involved in the coupling and suggest that some special feature of this region, probably different from simple masking of the initiation site by base pairing, is responsible for translational coupling. The present results also suggest that there might be specific differences in the primary nucleotide sequence that distinguish independent translational initiation sites from translationally coupled (i.e., masked) initiation sites.

A single base change in the Shine-Dalgarno region of 16S rRNA of Escherichia coli affects translation of many proteins

A single base mutation was constructed at position 1538 of Escherichia coli 16S rRNA, changing a cytidine to a uridine. This position is in the Shine-Dalgarno region, thought to be involved in base-pairing to mRNA during initiation of protein synthesis. The mutation was constructed by using a synthetic oligodeoxynucleotide that differs in sequence by one base from the wild-type sequence of 16S rRNA. This oligonucleotide was used as a primer on single-stranded DNA of phage M13, into which was cloned a specific region of DNA encoding 16S rRNA. The mutation is lethal when expressed from the normal promoters of rRNA operons, P1 and P2, in a high-copy-number plasmid. Expression can be repressed by a temperature-sensitive repressor, cI857, in combination with the bacteriophage lambda PL promoter. Induction of transcription by temperature shift yields mutant 16S rRNA that is processed and assembled into functional ribosomal subunits. The presence of mutant ribosomes retards cell growth and dramatically alters incorporation of [35S]methionine into a large proportion of the cellular proteins. The change in level of synthesis of individual proteins correlates with the change in base-pairing between mutant rRNA and the Shine-Dalgarno region of the mRNA.

More than 150 nucleotides flanking the initiation codon contribute to the efficiency of the ribosomal binding site from bacteriophage T7 gene 1

The ribosomal binding site (RBS) from gene 1 of bacteriophage T7 was isolated on fragments of differing length and cloned upstream of the mouse dihydrofolate reductase gene to control the translation of its sequence. A 29 base pair sequence containing all elements generally believed to be essential for the RBS's showed extremely low activity. Additional upstream and downstream sequences were required to obtain a several orders of magnitude higher efficiency. By contrast, areas further downstream than +112 nucleotides from the initiator proved to be inhibitory, whereas the presence of an upstream RNaseIII cleavage site showed a strong stimulatory effect. This suggests that tertiary structures are involved in the function of the RBS studied. The efficient RBS's were complexed by ribosomes at much lower concentrations of the mRNA than the weak ones.

Potential secondary structure at translation-initiation sites

Since translational start codons also occur internally, more-complex features within mRNA must determine initiation. We compare the potential secondary structure of 123 prokaryotic mRNA start regions to that of regions coding for internal methionines. The latter display an unexpectedly-uniform, almost-periodic pattern of pairing potential. In contrast, sequences 5' to start codons have little self-pairing, and do not pair extensively with the proximal coding region. Pairing potential surrounding start codons was found to be less than half of that found near internal AUGs. In groups of random sequences where the distribution of nucleotides at each position, or of trinucleotides at each in-frame codon position, matched the observed natural distribution, there was no periodicity in the pairing potential of the internal sequences. Randomized internal sequences had less pairing: the ratio of pairing intensity between internals and starts was reduced from 2.0 to 1.6 by randomization. We propose that the transition from the relatively-unstructured start domains to the highly-structured internal sequences may be an important determinant of translational start-site recognition.

Modification of mRNA secondary structure and alteration of the expression of human interferon alpha 1 in Escherichia coli

A plasmid (pNL015) was constructed to contain a human interferon alpha 1 (IFN-alpha 1) gene under the transcriptional control of the Escherichia coli lipoprotein promoter. The E. coli cells harboring this plasmid produce 2.8 x 10(4) units/ml of IFN. Secondary structure analysis of the transcripts produced by pNL015 showed that the coding region could base pair with the Shine-Dalgarno (SD) region with a delta G = -3.9kcal/mol. A new plasmid pNL008 was constructed by modifying pNL015 with an 11-bp deletion and a 2-bp insertion in the coding region, so that the SD region is not involved in the secondary structure. E. coli cells harboring pNL008 produce ten times more IFN activity than cells harboring pNL015. A series of experiments were carried out to show that the specific activities of IFN, differential rates of IFN transcription, protein degradation or mRNA degradation could not account for the difference observed in expression. A rigorous test on this model of translational inhibition was conducted by the construction of pNL017 with a single bp substitution which did not change the amino acid sequence of the IFN (synonymous codon substitution) but which increased the calculated energy of interaction with the SD sequence to delta G = -10.8 kcal/mol. The E. coli cells harboring pNL017 produced no detectable IFN activity.

A mutation allowing an mRNA secondary structure diminishes translation of Saccharomyces cerevisiae iso-1-cytochrome c

The CYC1-239-O mutation in the yeast Saccharomyces cerevisiae produces a -His-Leu- replacement of the normal -Ala-Gly- sequence at amino acid positions 5 and 6, which lie within a dispensable region of iso-1-cytochrome c; this mutation can accommodate the formation of a hairpin structure at the corresponding site in the mRNA. The amount of the altered protein was diminished to 20% of the wild-type level, whereas the amount of the mRNA remained normal. However, in contrast to the normal CYC1+ mRNA that is associated mainly with four to seven ribosomes, the bulk of the CYC1-239-O mRNA is associated with one to four ribosomes. These results suggest that the stable secondary structure within the translated region of the CYC1 mRNA diminishes translation by inhibiting elongation.

Use of a portable ribosome-binding site for maximizing expression of a eukaryotic gene in Escherichia coli

To maximize expression of a eukaryotic gene in Escherichia coli, a series of plasmids were constructed containing various synthetic ribosome-binding sites (RBS). These sites consist of a Shine-Dalgarno (SD) region (with translation stop codons in all three reading frames) positioned at distances 5-9 nucleotides (nt) from the AUG initiator codon of the gene coding for human T-cell growth factor (TCGF or IL-2). The region encompassing the RBS through the TCGF structural gene from each of these plasmids was inserted as a 'cassette' into seven different E. coli expression vectors, and TCGF production was measured. Our results demonstrate a greater than 2000-fold range of TCGF synthesis dependent upon the promoter and the synthetic RBS used. The translational efficiency of the TCGF gene was found to be influenced by the quality of the RBS, which is in part determined by the external sequence context of this site. The synthetic RBS, containing the necessary information for the translation initiation process, readily accessible by restriction sites, should be of general usefulness in obtaining maximum expression of eukaryotic genes in E. coli.

Enhancement of translational efficiency by the Escherichia coli atpE translational initiation region: its fusion with two human genes

The cDNA sequences encoding mature human interleukin 2 (IL2) and beta-interferon (INF beta), respectively, were fused with various translational initiation regions and inserted into two different types of expression vector. The relative levels of expression of the two genes and the functional stability of their respective mRNAs were examined in vivo in Escherichia coli hosts. The addition of the 30-bp sequence, found immediately upstream of the E. coli atpE gene Shine-Dalgarno (SD) sequence, to the translational initiation regions of IL2 and INF beta increased the expression of both these genes by a factor of 6-10. Thus this sequence, which naturally acts within the E. coli atp operon to enhance the translational initiation frequency of the atpE gene, can increase the expression of other genes in E. coli. It may exemplify a specific type of recognition signal for the E. coli translational apparatus.

Mechanism of translational coupling between coat protein and replicase genes of RNA bacteriophage MS2

We have analyzed the molecular mechanism that makes translation of the MS2 replicase cistron dependent on the translation of the upstream coat cistron. Deletion mapping on cloned cDNA of the phage shows that the ribosomal binding site of the replicase cistron is masked by a long distance basepairing to an internal coat cistron region. Removal of the internal coat cistron region leads to uncoupled replicase synthesis. Our results confirm the model as originally proposed by Min Jou et al. (1). Activation of the replicase start is sensitive to the frequency of upstream translation, but never reaches the level of uncoupled replicase synthesis.

A mutation allowing an mRNA secondary structure diminishes translation of Saccharomyces cerevisiae iso-1-cytochrome c

The CYC1-239-O mutation in the yeast Saccharomyces cerevisiae produces a -His-Leu- replacement of the normal -Ala-Gly- sequence at amino acid positions 5 and 6, which lie within a dispensable region of iso-1-cytochrome c; this mutation can accommodate the formation of a hairpin structure at the corresponding site in the mRNA. The amount of the altered protein was diminished to 20% of the wild-type level, whereas the amount of the mRNA remained normal. However, in contrast to the normal CYC1+ mRNA that is associated mainly with four to seven ribosomes, the bulk of the CYC1-239-O mRNA is associated with one to four ribosomes. These results suggest that the stable secondary structure within the translated region of the CYC1 mRNA diminishes translation by inhibiting elongation.

RNase-sensitive and RNase-insensitive protective components isolated from Listeria monocytogenes

Crude ribosomes were isolated from Listeria monocytogenes serotype 4b and separated into two fractions by molecular sieve chromatography. Chemical analysis indicated that fraction I contained cell envelope components while fraction II contained the ribosomes. Both fractions protected mice against Listeria, but only in combination with the adjuvant dimethyldioctadecylammonium bromide (DDA). RNase-treatment, but not proteinase K-treatment destroyed the protective properties of fraction II, and RNA purified from fraction II also induced protection. Protection induced by fraction I was not affected by either RNase- or proteinase K-treatment. Both subcutaneous and intraperitoneal, but not intravenous administration of fraction I, fraction II, or purified RNA induced significant protection against intraperitoneal infection, the intraperitoneal route of administration being the most effective. All preparations induced high levels of protection 3 to 7 days after administration, but protection was already decreased after 14 days. Protection induced with RNA appeared to be biphasic, because it also protected mice 1 day, but not 2 days after administration. Protection induced with both fraction I and RNA was at least in part non-specific, because both preparations also protected mice against L. monocytogenes serotype 3, Streptococcus pneumoniae and Pseudomonas aeruginosa. Results are discussed in relation to previous work with analogous preparations from P. aeruginosa.

Stabilisation of human interferon beta synthesis in Escherichia coli by zinc ions

Human interferon beta synthesized in Escherichia coli is unstable and toxic for the bacterial cell. Zinc ions are able to stabilise interferon beta in E. coli probably by inhibiting the action of cell internal proteinase(s) which affect the half-life of this foreign protein. As a result up to one order of magnitude more active IFN-beta can be detected in Zn2+-treated E. coli cells.

Effect of spermidine on the conformation of bacteriophage MS2 RNA. Electron microscopy and computer modeling

The structure of single-stranded RNA from the bacteriophage MS2 has been examined by electron microscopy in the presence of the polyamine spermidine. The molecules are found in two alternate conformations. The first of these can be characterized as a cruciform structure composed of three large loops approximately 500 to 700 nucleotides in size. The interior of the molecule has extensive base-paired regions which connect distant regions of the molecule; the farthest being 2500 nucleotides apart. In the second conformation, the molecules appear rod-like. Two of the large loops disappear, and these regions form, instead, extensive long-range helices. Computer modeling has been employed to explore the base-pairing potential of the sequence of bacteriophage MS2 RNA. Double-stranded regions identified by electron microscopy are shown to occur in local G + C-rich stretches of the RNA. Detailed models have been calculated for two regions of long-range contact. One of these includes the ribosome-binding site for the viral coat protein gene. The results are discussed in the context of the known role of RNA structure in the regulation of viral gene expression.

Alterations upstream from the Shine-Dalgarno region and their effect on bacterial gene expression

A vector containing the leftward promoter (pL) as transcription initiation signal and a synthetic, easily adaptable translation initiation region have been constructed. We have used the expression system to assess the relevance of sequences upstream from the Shine-Dalgarno (SD) region in the translational-initiation process. To this end, a series of structural variants of the prototype ribosome-binding site were used to direct the synthesis of both mature human fibroblast interferon and beta-galactosidase (beta-gal). It was found that alterations 5' to the SD element can considerably affect the rate of mRNA translation. The observation that the relative efficiency of the various 5'-untranslated regions depends on the downstream coding information implies that secondary (and/or tertiary) structure formation is of major importance in the initiation process. But an mRNA folding, in which the SD and ATG determinant are set free in single-stranded regions, does not unconditionally guarantee an efficient initiation of translation.

Translational interference at overlapping reading frames in prokaryotic messenger RNA

In overlapping reading frames of prokaryotic mRNA, the ribosome-binding site (RBS) of the downstream cistron is part of the coding sequence of the upstream message. We have examined whether the rate of translation in Escherichia coli can be sufficiently high to preclude the use of an RBS in initiation of protein synthesis when it is part of an actively decoded reading frame. The two sets of gene overlap present in the RNA phage MS2 are used as a model system. We find that translation of an upstream cistron can fully block initiation of protein synthesis at the overlapping RBS of the downstream cistron. Nonsense mutations in the upstream gene restore the translation of the downstream gene.

The influence of mRNA primary and secondary structure on human IFN-gamma gene expression in E. coli

Parameters influencing the efficiency of expression of the human immune interferon (IFN-gamma) gene in E. coli were studied by comparing a series of eight in vitro-derived gene variants. These contained all possible combinations of silent mutations in the first three codons of the mature IFN-gamma polypeptide coding sequence. Expression levels varied up to 50-fold among the different constructions. Comparison of messenger RNA secondary structure models for each variant suggested that the presence of stem-loop structures blocking the translation initiation signals could drastically decrease the efficiency of IFN-gamma synthesis. With variants displaying no stable mRNA secondary structure in the region, a C----U transition at position +11 after the AUG resulted in a 5-fold increase in expression indicating that RNA primary structure also plays an important role in expression. In addition we demonstrate that, in this system, a spacing of 8 nucleotides between the Shine-Dalgarno region and AUG was optimal for gene expression and that the steady-state production level of IFN-gamma rose exponentially with increasing rate of synthesis.

A versatile plasmid system for the study of prokaryotic transcription signals in Escherichia coli

For comparing the relative efficiencies of Escherichia coli promoters, a modified plasmid system, pKO-2 and pKM-2, has been constructed using short synthetic DNA fragments. The new vectors were derived from the plasmids pKO-1 and pKM-1. The plasmids contain seven clustered unique restriction sites which can be used for promoter insertions. Also, three adjacent stop codons were introduced to abort any undesired translational initiation from various upstream origins. The DNA sequence of any insert in pKO-2 and pKM-2 can be determined rapidly by the supercoiled plasmid DNA sequencing method using a single oligonucleotide primer. The plasmid pKM-2 is especially suitable for the cloning and sequence determination of strong promoters.

In vitro template activity of 0.3 mRNA from wild type and initiation mutants of bacteriophage T7

Bacteriophage T7 0.3 mRNA synthesised and processed in vitro has been purified starting from the DNA of T7+ as well as from that of two initiation mutants of T7 (CR17 with a U----C transition in the initiation codon and CR35b whose potential Shine and Dalgarno (S-D) interaction is interrupted by a G----A transition). These mRNAs were used as templates to direct the binding of fMet-tRNA and the synthesis of 0.3 protein in both E. coli and wheat germ cell-free systems. The initiation codon mutant displayed approximately 50% inhibition of fMet-tRNA binding and 0.3 protein synthesis in both systems. The S-D sequence mutant, on the other hand, was found to be less affected than the initiation triplet mutant (20%-40% inhibition) in both fMet-tRNA binding and template activity in the E. coli system. In the wheat germ system, which does not make use of the S-D interaction, however, this mutant displayed normal template activity suggesting that the inhibition obtained in the E. coli system, albeit slight, is due to the impairment of the S-D interaction and not to an alteration of the mRNA secondary or tertiary structure caused by the base substitution.